B T Volpe1, H I Krebs, N Hogan, L Edelstein OTR, C Diels, M Aisen. 1. Department of Neurology and Neuroscience, Cornell University Medical College, Burke Institute of Medical Research, White Plains, NY 10605, USA. volpe@rockvax.rockefeller.edu
Abstract
OBJECTIVE: In patients with stroke, the authors tested whether additional sensorimotor training of the paralyzed or paretic upper limb delivered by a robotic device enhanced motor outcome. METHODS:Fifty-six patients with stroke and hemiparesis or hemiplegia received standard poststroke multidisciplinary rehabilitation, and were randomly assigned either to receive robotic training (at least 25 hours) or exposure to the robotic device without training. Outcomes were assessed by the same masked raters, before treatment began and at the end of treatment, with the upper extremity component of the Fugl-Meyer Motor Assessment, the Motor Status score, the Motor Power score, and Functional Independence Measurement. RESULT: The robot treatment and control group had comparable clinical characteristics, lesion size, and pretreatment impairment scores. By the end of treatment, the robot-trained group demonstrated improvement in motor outcome for the trained shoulder and elbow (Motor Power score, p < 0.001; Motor Status score, p < 0. 01) that did not generalize to untrained wrist and hand. The robot-treated group also demonstrated significantly improved functional outcome (Functional Independence Measurement-Motor, p < 0. 01). CONCLUSION:Robot-delivered quantitative and reproducible sensorimotor training enhanced the motor performance of the exercised shoulder and elbow. The robot-treated group also demonstrated improved functional outcome. When added to standard multidisciplinary rehabilitation, robotics provides novel therapeutic strategies that focus on impairment reduction and improved motor performance.
RCT Entities:
OBJECTIVE: In patients with stroke, the authors tested whether additional sensorimotor training of the paralyzed or paretic upper limb delivered by a robotic device enhanced motor outcome. METHODS: Fifty-six patients with stroke and hemiparesis or hemiplegia received standard poststroke multidisciplinary rehabilitation, and were randomly assigned either to receive robotic training (at least 25 hours) or exposure to the robotic device without training. Outcomes were assessed by the same masked raters, before treatment began and at the end of treatment, with the upper extremity component of the Fugl-Meyer Motor Assessment, the Motor Status score, the Motor Power score, and Functional Independence Measurement. RESULT: The robot treatment and control group had comparable clinical characteristics, lesion size, and pretreatment impairment scores. By the end of treatment, the robot-trained group demonstrated improvement in motor outcome for the trained shoulder and elbow (Motor Power score, p < 0.001; Motor Status score, p < 0. 01) that did not generalize to untrained wrist and hand. The robot-treated group also demonstrated significantly improved functional outcome (Functional Independence Measurement-Motor, p < 0. 01). CONCLUSION: Robot-delivered quantitative and reproducible sensorimotor training enhanced the motor performance of the exercised shoulder and elbow. The robot-treated group also demonstrated improved functional outcome. When added to standard multidisciplinary rehabilitation, robotics provides novel therapeutic strategies that focus on impairment reduction and improved motor performance.
Authors: Hermano Igo Krebs; Bruce T Volpe; Dustin Williams; James Celestino; Steven K Charles; Daniel Lynch; Neville Hogan Journal: IEEE Trans Neural Syst Rehabil Eng Date: 2007-09 Impact factor: 3.802
Authors: Konstantinos P Michmizos; Stefano Rossi; Enrico Castelli; Paolo Cappa; Hermano Igo Krebs Journal: IEEE Trans Neural Syst Rehabil Eng Date: 2015-03-06 Impact factor: 3.802
Authors: Michael W O'Dell; Grace Kim; Lisa Rivera; Robert Fieo; Paul Christos; Caitlin Polistena; Kerri Fitzgerald; Delia Gorga Journal: J Rehabil Med Date: 2013-06 Impact factor: 2.912